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REAL OP-AMP LIMITATIONS

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Presentation on theme: "REAL OP-AMP LIMITATIONS"— Presentation transcript:

1 REAL OP-AMP LIMITATIONS
INPUT BIAS CURRENT, IBIAS INPUT OFFSET VOLTAGE, VOS BANDWIDTH RISE TIME & SLEW RATE

2 INPUT BIAS CURRENT Consider the analysis of op-amp inverting amplifier with IBIAS taken into account. RF R1 Vo I1 IF IBIAS +V -V V- V+

3 If the input to the above amplifier is grounded, then according to ideal characteristics, there should be no output, i.e. Vo should be 0V. As the + terminal is grounded, Writing KCL equations at the – terminal,

4 The value of R is chosen as (R1||RF).
Substituting for V-, (V- = 0) As stated earlier, IBIAS is very small, but when a large RF is used, there will be a considerable amount of voltage at the output. To correct this deviation of the real op-amp for ideal characteristics, a resistor R is usually connected to the + terminal. The value of R is chosen as (R1||RF).

5 Writing KCL equations at the - terminal,
RF R1 Vo I1 IF IBIAS +V -V V- V+ R In this case, Writing KCL equations at the - terminal,

6 Substituting for V- as, Now Vo is zero, as required.

7 INPUT OFFSET VOLTAGE Even when the bias current correcting resistor R is used, there could still be a few mV at the output when the inputs of the op-amp are grounded. To correct this problem, a small DC voltage can be applied at the input (+ve or –ve, as required) to drive the output voltage to zero. Known as input offset voltage, VOS

8 Figure shows the recommended setup for setting the input offset voltage.
10 k

9 BANDWIDTH The BW of an op-amp circuit depends on the ACL of the op-amp circuit. The BW limitation of an op-amp is specified by the GBW parameter in the op-amp data sheet. GBW is constant, i.e. if ACL higher, BW is lower and vice versa.

10 RISE TIME & SLEW RATE Rise Time, tr is a measure of how fast the op-amp responds to transient input. It is inversely proportional to the system BW. How to derive this equation, please refer to Appendix B (Floyd) page 941 ~ 942.

11 Power Supply Rejection Ratio
In practice, the power supply voltages change causing the dc biasing currents of the internal transistors to change. As a result, the VOS will also change. Also known as SVRR (Supply Voltage Rejection Ratio) or PSS (Power Supply Sensitivity)

12 example For 741 op-amp, PSRRmax = 150 V/V
If DC supply voltage change from VDC = 15V to 12V, Then,  VDC = 2 x 15 – 2 x 12 = 6 V And VOS = PSRR x  VDC = 900 V

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